Responses of the isolated anococcygeus muscle of the mouse to drugs and to field stimulation

Biology of the anococcygeus muscle

The anococcygeus is a smooth muscle tissue of the urogenital tract which, in the male, runs on to form the retractor penis. The motor innervation is classically sympathetic with noradrenaline as transmitter, but the relaxant parasympathetic transmitter has only recently been identified as nitric oxide. Indeed, the anococcygeus has provided an extremely useful model with which to probe the mechanisms underlying this novel nitrergic system, including the importance of physiological antioxidants in maintaining the potency of nitric oxide as a neurotransmitter. The cellular mechanisms of contraction and relaxation are slowly being clarified, with particular interest in the contribution of capacitative calcium entry and the guanylyl cyclase/cyclic GMP system. Many questions remain unanswered, however, including the precise physiological role of the muscle, the identity of substances released from subcellular vesicles of nitrergic nerves, the unusual sensitivity of the tissue to certain peptides (oxytocin and urotensin II), and the nature of store-operated channels through which calcium enters the cell to maintain contraction.

Localisation of nitric oxide synthase within non-adrenergic, non-cholinergic nerves in the mouse anococcygeus

Immunocytochemical staining of whole mount preparations of the mouse anococcygeus muscle, using antibodies to rat brain nitric oxide synthase (NOS), revealed a dense network of NOS-immunoreactive nerve fibres running through the tissue. These fibres were resistant to the sympathetic neurotoxin 6-hydroxydopamine and are therefore likely to be the non-adrenergic nerves which mediate relaxation of this smooth muscle. Further, NOS-immunoreactive fibres were absent following denervation by cold-storage (4 degrees C; 72 h), which has been shown to abolish non-adrenergic, non-cholinergic (NANC) relaxations. The results provide strong support for the hypothesis that the L-arginine:NO pathway is responsible for the generation of the NANC transmitter in the anococcygeus.

An investigation of some S-nitrosothiols, and of hydroxy-arginine, on the mouse anococcygeus

1. The effect of five S-nitrosothiols, and of the stereoisomers of NG-hydroxy-arginine (HOARG), were investigated on the mouse anococcygeus. 2. All five S-nitrosothiols produced concentration-related (0.1-100 microM) relaxations of carbachol (50 microM)-induced tone; the order of potency was S-nitroso-L-cysteine (CYSNO) > S-nitroso-N-acetyl-D,L-penicillamine (SNAP) > S-nitrosoglutathione (GSNO) > S-nitrosocoenzyme A (CoASNO) > S-nitroso-N-acetyl-L-cysteine (NACNO). The relaxations were unaffected by the nitric oxide synthase (NOS) inhibitor, L-NG-nitro-arginine (10 microM) (L-NOARG). 3. Cold-storage of the tissue for 72 h resulted in loss of sympathetic and non-adrenergic, non-cholinergic (NANC) nerve function. NOS activity in the tissue was reduced by 97%. Despite this, relaxations induced by the S-nitrosothiols were unaffected. 4. Haemoglobin (50 microM) attenuated relaxations induced by NO and the S-nitrosothiols, although responses to 3-isobutyl-1-methyl-xanthine were unaffected. N-methyl-hydroxylamine (2 mM) which has been shown previously to produce selective inhibition of NANC and nitrovasodilator responses in this tissue, also reduced responses to all S-nitrosothiols. 5. Hydroquinone (100 microM) greatly reduced relaxations to CYSNO (by 88%) but had no effect on those to SNAP, GSNO, CoASNO or NACNO. Since hydroquinone does not reduce responses to NANC stimulation, CYSNO is unlikely to be the NANC transmitter. 6. L-HOARG by itself (up to 100 microM) had no significant effect on carbachol-induced tone or on NANC (10 Hz; 10 strain every 100 s) relaxations. However, it produced reversal of the inhibitory effects of L-NOARG (10;pM), being only slightly less potent than L-arginine. D-HOARG was without effect.L-HOARG had no effect on relaxations induced by 1.51iM NO.7. The results show that S-nitrosothiols are potent relaxants of the mouse anococcygeus; they act directly on the smooth muscle with a mechanism similar to NO and other nitrovasodilators. In addition,the results are consistent with L-HOARG being an intermediate in the biosynthesis of NO from L-arginine, although there is no evidence for it acting to stabilize NO extracellularly.

Nitrergic transmission: nitric oxide as a mediator of non-adrenergic, non-cholinergic neuro-effector transmission

1. The possibility that transmission at some non-adrenergic, non-cholinergic (NANC) neuro-effector junctions is mediated by nitric oxide (NO) arose from the discoveries that NO mediated the effects of nitrovasodilator drugs and that endothelium-derived relaxing factor (EDRF) was NO or a NO-yielding substance. 2. NO donated by nitrovasodilator drugs or formed by endothelial cells activates soluble guanylate cyclase in smooth muscle and the consequent increase in cyclic guanosine monophosphate (cGMP) results in relaxation. The relaxations produced by stimulation of some NANC nerves are also due to a rise in cGMP. 3. The biosynthesis of NO by oxidation of a terminal guanidino nitrogen of L-arginine is inhibited by some NG-substituted analogues of L-arginine. These substances block EDRF formation by NO synthase and endothelium-dependent vasodilatation, and the blockade is overcome by L-arginine 4. NANC relaxations in some tissues are blocked by NG-substituted analogues of L-arginine and restored by L-arginine. Other agents that affect endothelium-dependent vasodilator responses produce corresponding changes in responses to stimulation of these NANC nerves. Such observations indicate that transmission is mediated by NO: we have termed this mode of transmission nitrergic. 5. There is evidence for nitrergic innervation of smooth muscle in the gastrointestinal tract, genito-urinary system, trachea and some blood vessels (penile and cerebral arteries). 6. The recognition of a mediator role for NO in neurotransmission calls for reconsideration of previously accepted generalizations about mechanisms of transmission. 7. Studies on nitrergic transmission will provide new insights into physiological control mechanisms and pathophysiological processes and may lead to new therapeutic developments.

Effects of omega-conotoxin GVIA on autonomic neuroeffector transmission in various tissues

1. The effects of omega-conotoxin GVIA (conotoxin), a potent inhibitor of neuronal N-type Ca2+ channels, have been examined on responses to stimulation of noradrenergic, cholinergic and non-adrenergic, non-cholinergic (NANC) nerves in a range of isolated tissues to investigate the role of conotoxin-sensitive Ca2+ channels in neurotransmission. 2. Contractions elicited by field stimulation of noradrenergic nerves in rat and mouse anococcygeus muscles, rabbit ear artery and rat vas deferens (epididymal portion) were inhibited by conotoxin. Responses to noradrenaline, and to adenosine triphosphate in the vas deferens, were not affected. 3. Positive chronotropic responses to field stimulation of noradrenergic nerves were inhibited by conotoxin in rat and mouse atria, but responses to noradrenaline and tyramine were not affected. 4. The stimulation-induced release of noradrenaline was inhibited by conotoxin in the rabbit ear artery and in rat and mouse atria. 5. Relaxations in response to stimulation of the noradrenergic perivascular mesenteric nerves were reduced or abolished by conotoxin in rat and rabbit jejunum. The response to noradrenaline in rat jejunum was not affected. 6. Contractions elicited by stimulation of cholinergic nerves were inhibited by conotoxin in rat jejunum and mouse ileum (perivascular mesenteric nerves), and in guinea-pig taenia caeci (field stimulation). Responses to acetylcholine in rat jejunum and mouse ileum were not affected. 7. Contractions elicited by stimulation of the cholinergic plus NANC pelvic nerves were inhibited by conotoxin in rabbit colon, and to a lesser extent in guinea-pig colon. The stimulation-induced contraction of the guinea-pig colon was inhibited by conotoxin by a greater proportion in the presence than in the absence of atropine. Responses to acetylcholine were not affected in the rabbit colon but were slightly reduced in the guinea-pig colon. 8. Relaxations in response to field stimulation of NANC nerves were inhibited by conotoxin in guinea-pig taenia caeci and rat gastric fundus strips, and in rat anococcygeus muscle when the tone was raised by guanethidine but not when it was raised by carbachol. The relaxations produced by sodium nitroprusside in the rat gastric fundus and anococcygeus were not affected. 9. Contractions of the rat bladder elicited by stimulation of the peri-urethral nerves, which are NANC- and cholinergically mediated, were relatively insensitive to inhibition by conotoxin. The response were almost completely abolished by tetrodotoxin. 10. The conotoxin-induced inhibitions of responses to nerve stimulation developed slowly and persisted after removal of conotoxin. The responses were almost completely abolished by tetrodotoxin. 10. The conotoxin-induced inhibitions of responses to nerve stimulation developed slowly and persisted after removal of conotoxin. 11. The inhibitory effect of conotoxin was inversely proportional to the frequency of stimulation (in several preparations) and to the Ca2+ concentration in the bathing solution (in rat vas deferens). These observations suggest that the inhibition by conotoxin of the Ca2+ influx required for excitation-secretion coupling in autonomic nerve terminals is not absolute, and can be overcome by repeated stimulation or by raising the Ca2 + concentration.

L-NG-monomethyl arginine and L-NG-nitro arginine inhibit non-adrenergic, non-cholinergic relaxation of the mouse anococcygeus muscle

1. The effects of L-NG-monomethyl arginine (L-NMMA) and L-NG-nitro arginine (L-NOARG) on non-adrenergic, non-cholinergic (NANC) relaxations of the mouse anococcygeus were investigated. 2. L-NMMA (10-200 microM) produced a concentration-related inhibition of the NANC response; the inhibitory effect of 50 microM L-NMMA was completely reversed by L-arginine but not D-arginine (both 100 microM). 3. L-NOARG (1-50 microM) also produced a concentration-related inhibition of the NANC response and was some 30-50 times more potent than L-NMMA; again, the effects of 10 microM L-NOARG were reversed by 100 microM L-, but not D-, arginine. By itself 100 microM L-arginine did not relax the tissue, but did cause a slight potentiation of the NANC response. 4. Sodium nitroprusside (0.01-10 microM), hydroxylamine (0.1-100 microM), sodium azide (1-100 microM) and nitric oxide (3-120 microM) all relaxed carbachol-induced tone; relaxations to submaximal concentrations of these nitrovasodilators were unaffected by either 50 microM L-NMMA or 10 microM L-NOARG. 5. L-NOARG 10 microM did not inhibit, but rather potentiated, contractions of the mouse anococcygeus due to stimulation of its sympathetic nerves. 6. The inhibitory effects of 10 microM L-NOARG on NANC relaxations were reversed by L-arginine (by 131%), L-citrulline (by 75%), L-arginine methyl ester (by 46%) and L-homoarginine (by 22%), but were unaffected by a variety of other amino acids and their derivatives (all at 100 microM). 7. The results provide strong evidence that NANC relaxations of the mouse anococcygeus are mediated by an endogenous nitrate material, probably derived from L-arginine, and confirm that L-NOARG provides a very useful and potent drug for the investigation of endogenous nitrate function.

The effect of Ca deprivation and of Ca-blocking drugs on oxytocin-induced contractions of the male mouse anococcygeus

Oxytocin (4 nM)-induced contractions of the male mouse anococcygeus were rapidly and completely lost in EGTA (2 mM)-containing, Ca-free Krebs solution. Contractions were also lost, although more slowly, in Ca-free Krebs solution without EGTA; under such conditions, readdition of Ca did not by itself cause contraction, but readdition of Ca (0.1-2.5 mM) in the presence of 4 nM oxytocin resulted in a rapid contractile response. These Ca-induced responses, in the presence of oxytocin, and those to oxytocin in normal Ca-containing Krebs solution, were unaffected by nitrendipine (0.01-1 microM). Contractions to oxytocin were completely blocked by the calmodulin antagonists trifluoperazine (50 microM) and W-7 (75 microM). It is concluded that oxytocin-induced contraction of the mouse anococcygeus does not require opening of nitrendipine-sensitive Ca channels, and there is no Ca-independent component of the contractile response; the cellular mechanisms linked to the oxytocin receptor in the anococcygeus are therefore different from those in the uterus.

N-methylhydroxylamine inhibits and M&B 22948 potentiates relaxations of the mouse anococcygeus to non-adrenergic, non-cholinergic field stimulation and to nitrovasodilator drugs

1. The effects of N-methylhydroxylamine (NMH) and of M&B 22948 on relaxations of the mouse anococcygeus to non-adrenergic, non-cholinergic (NANC) field stimulation and to a number of smooth muscle relaxant drugs were investigated. 2. Relaxations to NANC field stimulation (10 Hz; 60 s train) were reversibly blocked by NMH (1-5 mM), which also caused weak, transient reductions of carbachol (50 microM)-induced tone. N,N-dimethylhydroxylamine (2 mM) and hydroxylamine (5 microM) reduced tone to the same extent as NMH, but neither produced any inhibition of NANC relaxations. 3. M&B 22948 10 microM, which by itself reduced tone by 12%, potentiated submaximal but not maximal relaxations to NANC field stimulation; overall the log frequency-response curve was displaced to the left by a factor of 2. 4. Sodium nitroprusside (0.01-1 microM), hydroxylamine (0.5-100 microM), and nitric oxide (2-200 microM) all relaxed carbachol-induced tone; relaxations to submaximal concentrations of these nitrovasodilators were reduced in the presence of 2 mM NMH, and potentiated in the presence of 10 microM M&B 22948. 5. Neither NMH (2 mM) nor M&B 22948 (10 microM) affected relaxations induced by submaximal concentrations of vasoactive intestinal peptide (VIP; 1 microM), papaverine (10 microM), 3-isobutyl-1-methyl-xanthine (10 microM), or 8-bromo-cyclic guanosine monophosphate (100 microM); relaxations to adenosine 5'-triphosphate (ATP, 2 mM) were unaffected by M&B 22948, but were potentiated by NMH. 6. The selective inhibition by NMH, and potentiation by M&B 22948, of NANC and nitrovasodilator-induced relaxations of the mouse anococcygeus suggests that the NANC transmitter is neither VIP nor ATP, but resembles the nitrovasodilator drugs in its mode of action. The NANC transmission system is therefore similar to that recently described in the bovine retractor penis.

Electrophysiology of neuromuscular transmission in guinea-pig mesenteric veins

1. Neuromuscular transmission in the smooth muscle of mesenteric veins has been investigated by recording intracellular potential changes resulting from stimulation of the sympathetic nerves and comparing these potential changes with responses obtained by ionophoresis of noradrenaline. 2. Neural stimulation or exogenous noradrenaline acted similarly to cause two excitatory depolarizations, a slow response reported previously (Suzuki, 1981) and a separate fast depolarization. 3. The fast depolarization was distinct from the slow depolarizing response in that it had a different dependence on the level of stimulation, was readily desensitized and was more suppressed in low-chloride solution. 4. The fast but not the slow depolarization shared certain characteristics with constriction. The fast depolarization and constriction both increased with the intensity of stimulation; inactivation in both was dependent on the recovery interval between trains of stimuli and both were suppressed to a similar degree by antagonists to alpha-adrenoceptors. The fast depolarization was, however, not a prerequisite for constriction to occur. 5. The fast and slow depolarizations were activated after a long latency which had a high temperature coefficient consistent with the postulate that these responses are rate limited by intracellular biochemical reactions. 6. The fast depolarization was preferentially suppressed by prazosin, an antagonist to the alpha 1-adrenoceptor subtype. Suppression of the slow depolarization required relatively higher concentrations of antagonist, indicating that these responses were mediated by receptor interactions involving a different alpha-adrenoceptor subtype. 7. It is concluded that neuromuscular transmission in mesenteric veins occurs through activation of alpha-adrenoceptors. A number of responses result, including voltage-independent constriction and two distinct excitatory depolarizations which can lead to voltage-dependent constriction.

Agonist profile of ergometrine (ergonovine) on a population of postsynaptic alpha-adrenoceptors

Ergometrine (0.02-5 microM) produced concentration-related contractions of the mouse anococcygeus muscle, which were unaffected by cocaine (2 microM) or by pretreatment of mice with 6-hydroxydopamine. Contractions were reduced by alpha-adrenoceptor antagonists; the rank order of potency was prazosin greater than phentolamine greater than yohimbine. With phenoxybenzamine as antagonist, the estimated dissociation constant (KD) for ergometrine was 0.41 microM. It is concluded that ergometrine causes direct activation of postsynaptic alpha 1-adrenoceptors, and it is suggested that it acts on the same subtype of the receptor as imidazoline agonists.

Effects of VIP and related peptides and Gila monster venom on genitourinary smooth muscle

The pharmacological effects of peptide histidine isoleucine (PHI), glucagon and secretin were compared with vasoactive intestinal polypeptide (VIP) on rabbit urethra and anococcygeus muscle. VIP and PHI dose-dependently inhibited induced contractions of both smooth muscle preparations. Cross-tachyphylaxis between VIP and PHI was demonstrated in the urethra preparation, suggesting that their activity is mediated via a common receptor or second messenger. Glucagon and secretin were without effect on either preparation. Radioimmunoassays demonstrated substantial concentrations of VIP and PHI in both urethra and anococcygeus tissue extracts. These observations suggest that PHI is an additional candidate together with VIP to mediate relaxation of rabbit urethra and anococcygeus muscle. When compared with VIP, Gila monster venom was found to inhibit both smooth muscle preparations, producing concentration-response curves parallel to those produced by VIP.

An oxytocin receptor in anococcygeus muscles isolated from male mice

The nature of the neurohypophyseal peptide receptor in the anococcygeus muscles from male mice was investigated. The rank order of potency of naturally occurring peptides was oxytocin greater than Arg-vasotocin greater than Arg-vasopressin greater than Lys-vasopressin, which is similar to that found in the uterus and mammary gland. Selective agonists on the oxytocin (OT) receptors of the uterus and mammary gland (Thr4-OT; Gly7-OT; Thr4-Gly7-OT) were also potent agonists in the mouse anococcygeus. Competitive antagonists of uterine responses to oxytocin (dP-TyrMe-Thr4-OT; dP-TyrMe-OT; dP-Thr4-OT; dp-Orn8-OT) were also competitive antagonists of oxytocin-induced contractions of the mouse anococcygeus. It is concluded that the neurohypophyseal peptide receptor of the male mouse anococcygeus is of the oxytocin type; antagonist pA2 values suggest that this receptor resembles, but may not be identical to, the uterine oxytocin receptor. Possible physiological and pharmacological implications of these observations are discussed.

Magnesium ions and oxytocin sensitivity of the male mouse anococcygeus

The sensitivity of the mouse anococcygeus to contraction by oxytocin was shown to be Mg2+-dependent. Decreasing [Mg2+]0 from the optimal concentration of 1 to 0 mM caused a 20-fold parallel rightward displacement of the oxytocin dose-response curve. Contractions to oxytocin-related peptides (Arg-vasotocin, Arg-vasopressin and Lys-vasopressin) were also Mg2+-dependent, but those to other drugs (carbachol, methoxamine and thyrotrophin releasing hormone) were not. The onset of the potentiating effect of Mg2+ was rapid, full potentiation occurring within 70 s. 1-Deaminopenicillamine 8-ornithine-vasotocin produced competitive antagonism of responses to oxytocin, but was more potent in the absence (pA2 = 8.01) than in the presence of Mg2+ (1 mM; pA2 = 7.52). Thus, physiological concentrations of [Mg2+]0 enhanced oxytocin agonist potency but decreased oxytocin antagonist potency; possible mechanisms are discussed.

Evidence for two mechanisms of depolarization associated with alpha 1-adrenoceptor activation in the rat anococcygeus muscle

Membrane potential responses in the rat isolated anococcygeus to bath-applied noradrenaline and field stimulation have been investigated by use of intracellular microelectrode and combined extracellular electrical and mechanical (sucrose gap) recording techniques. Intracellular recordings were made usually from tissues immobilized with hypertonic Krebs solution. Bath-application of noradrenaline produced depolarizations which consisted of two components; an initial 'fast' phase which peaked within 1-2 s and which was followed by a 'slow' sustained depolarization. Both components were concentration-dependent. Noradrenaline could also evoke oscillations in membrane potential which, unlike the 'fast' component of depolarization, were prevented by conditioning hyperpolarization of the membrane and were evoked by direct membrane depolarization with externally applied current pulses. Thus, the oscillations are voltage-dependent phenomena. Replacement of the external NaCl of the Krebs solution with an equimolar amount of Na benzenesulphonate abolished the noradrenaline-evoked 'fast' depolarization while the 'slow' phase was unaffected. This suggests that two mechanisms of depolarization are activated in this muscle by the bath-application of noradrenaline. The adrenergic excitatory junction potential was also abolished in Na benzenesulphonate. Prazosin reduced both the 'fast' and 'slow' components of depolarization produced by noradrenaline indicating their mediation by alpha 1-adrenoceptors. The membrane potential (-29 mV) at the maximum amplitude of the 'fast' depolarization was similar to the equilibrium potential (-27 mV) for the depolarization evoked by ionophoretically applied noradrenaline and which was obtained by extrapolation from the relationship between amplitude of the ionophoretic response and membrane potential displacement in the partition chamber. These results suggest that the 'fast' depolarization and the ionophoretic response are due to an increased membrane conductance, possibly to chloride.

The mouse anococcygeus muscle as a preparation for the bioassay of oxytocin

Oxytocin (0.1-10 nM) caused reproducible, dose-related contractions of the male mouse anococcygeus. Desensitization was not a major problem. The muscle was shown to be a useful oxytocin bioassay preparation, having a good index of precision (0.04).

Neuropeptide-induced contraction and relaxation of the mouse anococcygeus muscle

Isometric tension responses to neuropeptides were recorded from anococcygeus muscles isolated from male mice. This smooth muscle tissue is innervated by inhibitory nonadrenergic, noncholinergic nerves that resemble, ultrastructurally, the peptidergic neurons of the gastrointestinal tract; the physiological function of the anococcygeus is not known. Slow sustained contractions were produced by oxytocin (0.2-20 nM), [Arg8]vasopressin (0.4-200 nM), and [Arg]-vasotocin (0.4-100 nM); the mouse anococcygeus is, therefore, one of the few examples of nonvascular smooth muscle from male mammals to respond to low concentrations of oxytocin and related peptides. Substance P (0.5-8 microM) caused distinctive, biphasic increases in muscle tone of some, but not all, preparations. Other neuropeptides producing contractions were neurotensin (2-100 microM) and thyrotropin-releasing hormone (2-100 microM); the responses were of similar time course and displayed selective cross-desensitization, suggesting that these two peptides act through a common distinct mechanism. Tetradecapeptide somatostatin (10-80 microM) and its analog urotensin II (0.1-5 microM), a dodecapeptide from the urophysis of the teleost fish Gillichthys mirabilis, produced similar slowly developing relaxations of carbachol-induced tone. Piscine urotensin II, of which there are no reported effects on nonvascular mammalian systems, was 20-50 times more potent than somatostatin, a well-established mammalian hormone. Of the peptides studied, only vasoactive intestinal polypeptide (0.05-1 microM) caused rapid powerful relaxations in low concentrations; this is consistent with its proposed involvement in nonadrenergic, noncholinergic neurotransmission in the mouse anococcygeus.

Biphasic non-adrenergic, non-cholinergic relaxations of the mouse anococcygeus muscle

Trains of field stimulation of 60 s duration caused a biphasic relaxation of carbachol (50 microM)-induced tone in the mouse anococcygeus. The optimal pulse frequency and width were 10 Hz and 1 ms respectively. Tetrodotoxin (31, 124, and 310 nM) caused a dose-dependent reduction in the magnitude of both phases. Neither phase was affected by (+/-)-propranolol (1 microM), neostigmine (1 microM), (+)-tubocurarine (100 microM), or apamin (500 nM). Biphasic relaxations were observed in muscles from 6-hydroxydopamine pretreated mice. Haemolysed blood (10, 40, and 100 microliter/ml) reduced the magnitude of the first phase of nerve-induced relaxation to a greater extent than the second. This effect was reversible. Following a prolonged train of inhibitory nerve stimulation (10 Hz; 10 min) the magnitude of the first phase was reduced only slightly, but the second markedly. The possible relationships between the biphasic relaxation to field stimulation and putative non-adrenergic, non-cholinergic transmitters in the mouse anococcygeus are discussed.

Membrane potential responses to ionophoretically applied alpha-adrenoceptor agonists in the mouse anococcygeus muscle

1 Noradrenaline phenylephrine, naphazoline and oxymetazoline were applied by ionophoresis to the mouse anococcygeus muscle and the membrane potential was recorded with an intracellular microelectrode. 2 The ionophoretic application of noradrenaline and phenylephrine produced dose-related depolarizations in 96% of the cells tested; in contrast, naphazoline and oxymetazoline depolarized only 62% of the cells although contraction was always seen. 3 The depolarizations produced by all four drugs had similar characteristics in shape and time course except that the latency of responses induced by the imidazoline-related drugs was significantly longer than the value obtained with the phenylethanolamines. This discrepancy was not due to the difference in susceptibility to neuronal uptake of the two groups of drugs. 4 The time to peak depolarization for naphazoline and oxymetazoline was longer than that for noradrenaline and phenylephrine but was not sufficient to account for the considerably slower contraction produced by the former drugs. 5 At room temperature the sensitivity of the mouse anococcygeus to ionophoretically applied naphazoline and oxymetazoline was significantly lower than that to noradrenaline and phenylephrine but at 35 degrees C the sensitivity was similar for all drugs. 6 These results suggest that there might be two subclasses of alpha 1-adrenoceptor in the mouse anococcygeus; stimulation of one type leads to depolarization and contraction and activation of the other class produces contraction with no change in membrane potential.

Pharmacology of postsynaptic alpha-adrenoreceptors in the mouse anococcygeus muscle

1. The alpha-adrenoreceptor agonists noradrenaline (NA), methoxamine, phenylephrine, naphazoline, oxymetazoline, and xylazine produced contractions of the mouse anococcygeus muscle. All were full agonists. 2. Cocaine (2 microM) increased the pD2 values of NA and phenylephrine. 6-hydroxydopamine pretreatment increased the pD2 values of NA, phenylephrine, and xylazine. After both procedures the order of potency of the agonists was oxymetazoline greater than naphazoline greater than NA greater than phenylephrine greater than methoxamine greater than xylazine. 3. The order of potency of antagonists against all six agonists was prazosin greater than phentolamine greater than yohimbine. However, from differences in the pA2 values and slopes of the Schild plots of the antagonists it was possible to distinguish three distinct groups of agonists: the phenylethylamines; the imidazolines; and the thiazine derivative xylazine. 4. The results suggest that the postsynaptic alpha-adrenoreceptor of the mouse anococcygeus muscle may be broadly classified as alpha 1. However, there may be at least three drug recognition sites on the receptor which interact with agonists of differing chemical structure.

The effects of vasoactive intestinal polypeptide and of adenosine 5'-triphosphate on the isolated anococcygeus muscle of the mouse

1 Vasoactive intestinal polypeptide (VIP, 0.01- MicroM) produced dose-related relaxations of the mouse anococcygeus muscle. 2 Following incubation with indomethacin (2.8 microM 1 h) adenosine 5'-triphosphate (ATP, 0.5-10 mM) produced dose-related relaxations of the mouse anococcygeus. 3 Haemolysed blood reduced inhibitory responses of the mouse anococcygeus to field stimulation but had no effect on relaxations to VIP or ATP. 4 Apamin (0.5 microM) had no effect on the relaxation of mouse anococcygeus to field stimulation, VIP, or ATP. 5 2-2'-Pyridylisatogen tosylate (PIT, 50 microM) itself reduced muscle tone but it did not abolish inhibitory responses to field stimulation, VIP, or ATP. 6 During prolonged inhibitory nerve stimulation the relaxation of the mouse anococcygeus in response to VIP was reduced greatly while that to ATP was unaffected. 7 Bundles of VIP-immunoreactive sites were detected in sections of the mouse anococcygeus treated by the peroxidase-antiperoxidase (PAP) immunocytochemical technique. 8 The results suggest that the mechanisms underlying non-adrenergic, non-cholinergic inhibitory transmission in the mouse anococcygeus are similar to those in the bovine retractor penis and unlike those in the guinea-pig taenia caeci. 9 The possibility that VIP or ATP might be involved in inhibitory neurotransmission in the mouse anococcygeus is discussed.

Membrane potential responses of the mouse anococcygeus muscle to ionophoretically applied noradrenaline

1. Membrane potential responses to ionophoretically applied noradrenaline and to field stimulation were studied in the mouse anococcygeus muscle using intracellular recording techniques.2. The ionophoretic application of noradrenaline produced charge-dependent depolarizations whose total duration was 1-2 s at room temperature and which were characterized by a delay between the start of the ionophoretic pulse and the onset of depolarization (termed the latency of the responses). On occasion ionophoresis of noradrenaline did not depolarize the muscle even though it seemed that successful ejection of noradrenaline had occurred as small localized contractions could be seen.3. The characteristics of these depolarizations were unaffected by tetrodotoxin (10(-7) M) and could not be reproduced when the ionophoretic pipette contained 2 M-NaCl rather than noradrenaline. Moreover noradrenaline still produced depolarizations in denervated muscle and thus it is concluded that the responses were caused by noradrenaline released from the ionophoretic micropipette and not from the intrinsic noradrenergic nerves.4. Field stimulation of innervated muscle usually evoked excitatory junction potentials (e.j.p.s), but sometimes inhibitory junction potentials (i.j.p.s) or a mixture of e.j.p.s and i.j.p.s were observed. The time course of the e.j.p.s was slightly longer than that of the ionophoretic depolarizations which was accounted for by a smaller latency of the ionophoretically induced responses.5. The pharmacology of the nerve-evoked e.j.p.s and the ionophoretically induced depolarizations was similar as both types of responses were antagonized by alpha(1)-adrenoceptor blocking agents (phentolamine and prazosin) but were unaffected by the beta-adrenoceptor antagonist, propranolol. It is probable that noradrenaline released from the intrinsic nerves and that from the ionophoretic micropipette were acting on the same adrenoceptors.6. The latency and to a lesser extent the rise-time of the depolarizations produced by the ionophoretic application of noradrenaline was highly sensitive to changes in temperature of the bathing fluid (Q(10)s > 2) whereas the half-decay time was relatively insensitive to temperature changes (Q(10) approximately 1.5). In addition the latency of the depolarizations was not altered by inhibiting the noradrenaline-uptake mechanism with cocaine (2 x 10(-6) M) or by alpha-adrenoceptor blocking agents. Thus it seems likely that the latency of the responses is a property of the noradrenaline-receptor interaction rather than being caused by other phenomena such as diffusion of noradrenaline.